Cerium is a chemical element; it has Chemical symbol Ce and atomic number 58. It is a hardness, ductile, and silvery-white metal that tarnishes when exposed to air. Cerium is the second element in the lanthanide series, and while it often shows the oxidation state of +3 characteristic of the series, it also has a stable +4 state that does not oxidize water. It is considered one of the rare-earth elements. Cerium has no known biological role in humans but is not particularly toxic, except with intense or continued exposure.
Despite always occurring in combination with the other rare-earth elements in minerals such as those of the monazite and bastnäsite groups, cerium is easy to extract from its ores, as it can be distinguished among the lanthanides by its unique ability to be oxidized to the +4 state in aqueous solution. It is the most common of the lanthanides, followed by neodymium, lanthanum, and praseodymium. Its estimated abundance in the Earth's crust is 68 ppm.
Cerium was the first of the lanthanides to be discovered, in Bastnäs, Sweden. It was discovered by Jöns Jakob Berzelius and Wilhelm Hisinger in 1803, and independently by Martin Heinrich Klaproth in Germany in the same year. In 1839 Carl Gustaf Mosander separated cerium(III) oxide from other rare earths, and in 1875 William Francis Hillebrand became the first to isolate the metal. Today, cerium and its compounds have a variety of uses: for example, cerium(IV) oxide is used to polish glass and is an important part of catalytic converters. Cerium metal is used in ferrocerium lighters for its pyrophoric properties. Cerium-doped YAG phosphor is used in conjunction with blue light-emitting diodes to produce white light in most commercial white LED light sources.
Characteristics
Physical
Cerium is the second element of the
lanthanide series. In the periodic table, it appears between the lanthanides
lanthanum to its left and
praseodymium to its right, and above the
actinide thorium. It is a
ductile metal with a hardness similar to that of
silver.
Its 58 electrons are arranged in the configuration Xe4f5d6s, of which the four outer electrons are
. The 4f, 5d, and 6s energy levels are very close to each other, and the transfer of one electron to the 5d shell is due to strong interelectronic repulsion in the compact 4f shell. This effect is overwhelmed when the atom is positively ionised; thus Ce on its own has instead the regular configuration Xe4f, although in some solid solutions it may be Xe4f5d.
Most lanthanides can use only three electrons as valence electrons, as afterwards the remaining 4f electrons are too strongly bound: cerium is an exception because of the stability of the empty f-shell in Ce and the fact that it comes very early in the lanthanide series, where the nuclear charge is still low enough until
neodymium to allow the removal of the fourth valence electron by chemical means.
Cerium has a variable electronic structure. The energy of the 4f electron is nearly the same as that of the outer 5d and 6s electrons that are delocalized in the metallic state, and only a small amount of energy is required to change the relative occupancy of these electronic levels. This gives rise to dual valence states. For example, a volume change of about 10% occurs when cerium is subjected to high pressures or low temperatures. In its high pressure phase (α-Cerium), the 4f electrons are also delocalized and itinerate, as opposed to localized 4f electrons in low pressure phase (γ-Cerium).
Chemical properties of the element
Like the other lanthanides, cerium metal is a good
reducing agent, having standard reduction potential of
E = −2.34 V for the Ce/Ce couple. It tarnishes in air, forming a passivating oxide layer like
iron rust. A centimeter-sized sample of cerium metal corrodes completely in about a year. More dramatically, metallic cerium can be highly
pyrophoric:
Being highly electropositive, cerium reacts with water. The reaction is slow with cold water but speeds up with increasing temperature, producing cerium(III) hydroxide and hydrogen gas:
Allotropes
Four
allotropy forms of cerium are known to exist at standard pressure and are given the common labels of α to δ:
-
The high-temperature form, δ-cerium, has a bcc (body-centered cubic) crystal structure and exists above 726 °C.
-
The stable form below 726 °C to approximately room temperature is γ-cerium, with an fcc (face-centered cubic) crystal structure.
-
The DHCP (double hexagonal close-packed) form β-cerium is the equilibrium structure approximately from room temperature to −150 °C.
-
The fcc form α-cerium is stable below about −150 °C; it has a density of 8.16 g/cm.
-
Other solid phases occurring only at high pressures are shown on the phase diagram.
-
Both γ and β forms are quite stable at room temperature, although the equilibrium transformation temperature is estimated at 75 °C.
At lower temperatures the behavior of cerium is complicated by the slow rates of transformation. Transformation temperatures are subject to substantial hysteresis and values quoted here are approximate. Upon cooling below −15 °C, γ-cerium starts to change to β-cerium, but the transformation involves a volume increase and, as more β forms, the internal stresses build up and suppress further transformation.
Isotopes
- All nuclear data not otherwise stated is from the standard source:
Naturally occurring cerium is made up of four isotopes: Ce (0.19%), Ce (0.25%), Ce (88.45%), and Ce (11.11%). All are observationally stable, though the light isotopes Ce and Ce are theoretically expected to undergo double electron capture to isotopes of
barium, and the heaviest isotope
142Ce is expected to undergo double beta decay to
142Nd or alpha decay to
138Ba. Thus,
140Ce is the only theoretically
stable isotope. None of these decay modes have yet been observed, though the double beta decays of
136Ce,
138Ce, and
142Ce have been experimentally searched for. The current experimental limits for their half-lives are about 1×10
17, 4×10
17, and 3×10
18 years - all short compared to known double-beta half-lives.
All other cerium isotopes are synthetic and radioactivity. The most stable of them are 144Ce with a half-life of 284.9 days, 139Ce with a half-life of 137.6 days, and 141Ce with a half-life of 32.5 days. All other radioactive cerium isotopes have half-lives under four days, and most of them have half-lives under ten minutes. The isotopes between 140Ce and 144Ce inclusive occur as of uranium. The primary decay mode of the isotopes lighter than 140Ce is inverse beta decay or electron capture to isotopes of lanthanum, while that of the heavier isotopes is beta decay to isotopes of praseodymium. Some isotopes of neodymium can alpha decay or are predicted to decay to isotopes of cerium.
Compounds
Cerium exists in two main oxidation states, Ce(III) and Ce(IV). This pair of adjacent oxidation states dominates several aspects of the chemistry of this element. Cerium(IV) aqueous solutions may be prepared by reacting cerium(III) solutions with the strong oxidizing agents
peroxodisulfate or
bismuthate. The value of
E(Ce/Ce) varies widely depending on conditions due to the relative ease of complexation and hydrolysis with various anions, although +1.72 V is representative. Cerium is the only lanthanide which has important aqueous and coordination chemistry in the +4 oxidation state.
Halides
Cerium forms all four trihalides CeX (X = F, Cl, Br, I) usually by reaction of the oxides with the hydrogen halides. The anhydrous halides are pale-colored, paramagnetic, hygroscopic solids. Upon hydration, the trihalides convert to complexes containing aquo complexes Ce(HO). Unlike most lanthanides, Ce forms a tetrafluoride, a white solid. It also forms a bronze-colored diiodide, which has metallic properties. Aside from the binary halide phases, a number of anionic halide complexes are known. The fluoride gives the Ce(IV) derivatives and . The chloride gives the orange .
Oxides and chalcogenides
Cerium(IV) oxide ("ceria") has the
fluorite structure, similarly to the dioxides of praseodymium and
terbium. Ceria is a nonstoichiometric compound, meaning that the real formula is CeO, where x is about 0.2. Thus, the material is not perfectly described as Ce(IV). Ceria reduces to cerium(III) oxide with hydrogen gas. Many nonstoichiometric
are also known, along with the trivalent CeZ (Z =
sulfur,
selenium,
tellurium). The monochalcogenides CeZ conduct electricity and would better be formulated as CeZe. While CeZ are known, they are polychalcogenides with cerium(III): cerium(IV) derivatives of S, Se, and Te are unknown.
Cerium(IV) complexes
The compound ceric ammonium nitrate (CAN) is the most common cerium compound encountered in the laboratory. The six nitrate ligands bind as
. The complex is 12-coordinate, a high coordination number which emphasizes the large size of the Ce
4+ ion. CAN is a popular oxidant in organic synthesis, both as a stoichiometric reagent
and as a catalyst.
It is inexpensive, stable in air, easily handled, and of low toxicity.
It operates by one-electron redox. Cerium nitrates also form 4:3 and 1:1 complexes with 18-crown-6 (the ratio referring to that between the nitrate and the
crown ether). Classically, CAN is a primary standard for quantitative analysis.
Cerium(IV) salts, especially cerium(IV) sulfate, are often used as standard reagents for volumetric analysis in
cerimetry.
Due to ligand-to-metal charge transfer, aqueous cerium(IV) ions are orange-yellow.
Organocerium compounds
Organocerium chemistry is similar to that of the other lanthanides, often involving complexes of
cyclopentadienyl and cyclooctatetraenyl ligands.
Cerocene adopts the
uranocene molecular structure. The 4f electron in cerocene is poised ambiguously between being localized and delocalized and this compound is considered intermediate-valent.
,
alkynyl, and
alkenyl organocerium derivatives are prepared from the
transmetallation of the respective
organolithium or
Grignard reagent reagents, and are more
Nucleophile but less basic than their precursors.
History
Cerium was discovered in Bastnäs in Sweden by Jöns Jakob Berzelius and
Wilhelm Hisinger, and independently in Germany by Martin Heinrich Klaproth, both in 1803.
Cerium was named by Berzelius after the asteroid Ceres, formally 1 Ceres, discovered two years earlier.
Ceres was initially considered to be a planet at the time. The asteroid is itself named after the Roman goddess Ceres, goddess of agriculture, grain crops, fertility and motherly relationships.
Cerium was originally isolated in the form of its oxide, which was named ceria, a term that is still used. The metal itself was too electropositive to be isolated by then-current smelting technology, a characteristic of rare-earth metals in general. After the development of electrochemistry by Humphry Davy five years later, the earths soon yielded the metals they contained. Ceria, as isolated in 1803, contained all of the lanthanides present in the cerite ore from Bastnäs, Sweden, and thus only contained about 45% of what is now known to be pure ceria. It was not until Carl Gustaf Mosander succeeded in removing lanthana and Didymium in the late 1830s that ceria was obtained pure. Wilhelm Hisinger was a wealthy mine-owner and amateur scientist, and sponsor of Berzelius. He owned and controlled the mine at Bastnäs, and had been trying for years to find out the composition of the abundant heavy gangue rock (the "Tungsten of Bastnäs", which despite its name contained no tungsten), now known as cerite, that he had in his mine.
The element played a role in the Manhattan Project, where cerium compounds were investigated in the Calutron site as materials for for uranium and plutonium casting.
Occurrence and production
Cerium is the most abundant of all the lanthanides and the 25th most abundant element, making up 68 ppm of the Earth's crust.
This value is the same of
copper, and cerium is even more abundant than common metals such as
lead (13 ppm) and
tin (2.1 ppm). Thus, despite its position as one of the so-called
, cerium is actually not rare at all. Cerium content in the soil varies between 2 and 150 ppm, with an average of 50 ppm; seawater contains 1.5 parts per trillion of cerium.
Cerium occurs in various minerals, but the most important commercial sources are the minerals of the
monazite and bastnäsite groups, where it makes up about half of the lanthanide content. Monazite-(Ce) is the most common representative of the monazites, with "-Ce" being the Levinson suffix informing on the dominance of the particular REE element representative.
Also the cerium-dominant bastnäsite-(Ce) is the most important of the bastnäsites.
Cerium is the easiest lanthanide to extract from its minerals because it is the only one that can reach a stable +4 oxidation state in aqueous solution. Because of the decreased solubility of cerium in the +4 oxidation state, cerium is sometimes depleted from rocks relative to the other rare-earth elements and is incorporated into
zircon, since Ce
4+ and
zirconium4+ have the same charge and similar ionic radii.
In extreme cases, cerium(IV) can form its own minerals separated from the other rare-earth elements, such as
cerianite-(Ce)
and .
Bastnäsite, LnCOF, is usually lacking in thorium and the heavy lanthanides beyond samarium and europium, and hence the extraction of cerium from it is quite direct. First, the bastnäsite is purified, using dilute hydrochloric acid to remove calcium carbonate impurities. The ore is then roasted in the air to oxidize it to the lanthanide oxides: while most of the lanthanides will be oxidized to the sesquioxides , cerium will be oxidized to the dioxide CeO. This is insoluble in water and can be leached out with 0.5 M hydrochloric acid, leaving the other lanthanides behind.
The procedure for monazite, , which usually contains all the rare earths, as well as thorium, is more involved. Monazite, because of its magnetic properties, can be separated by repeated electromagnetic separation. After separation, it is treated with hot concentrated sulfuric acid to produce water-soluble sulfates of rare earths. The acidic filtrates are partially neutralized with sodium hydroxide to pH 3–4. Thorium precipitates out of solution as hydroxide and is removed. After that, the solution is treated with ammonium oxalate to convert rare earths to their insoluble . The oxalates are converted to oxides by annealing. The oxides are dissolved in nitric acid, but cerium oxide is insoluble in HNO3 and hence precipitates out.
Applications
Cerium has two main applications, both of which use CeO
2. The industrial application of ceria is for polishing, especially chemical-mechanical planarization (CMP). In its other main application, CeO
2 is used to decolorize glass. It functions by converting green-tinted ferrous impurities to nearly colorless ferric oxides.
[.] Ceria has also been used as a substitute for its radioactive congener
thorium dioxide, for example in the manufacture of electrodes used in gas tungsten arc welding, where cerium as an alloying element improves arc stability and ease of starting while decreasing burn-off.
Gas mantles and pyrophoric alloys
The first use of cerium was in
, invented by Austrian chemist Carl Auer von Welsbach. In 1885, he had previously experimented with mixtures of
magnesium, lanthanum, and yttrium oxides, but these gave green-tinted light and were unsuccessful.
Six years later, he discovered that pure
thorium oxide produced a much better, though blue, light, and that mixing it with cerium dioxide resulted in a bright white light.
Cerium dioxide also acts as a catalyst for the combustion of thorium oxide.
This resulted in commercial success for von Welsbach and his invention, and created great demand for thorium. Its production resulted in a large amount of lanthanides being simultaneously extracted as by-products. Applications were soon found for them, especially in the pyrophoric alloy known as "mischmetal" composed of 50% cerium, 25% lanthanum, and the remainder being the other lanthanides, that is used widely for lighter flints. Usually iron is added to form the alloy ferrocerium, also invented by von Welsbach.[Klaus Reinhardt and Herwig Winkler in "Cerium Mischmetal, Cerium Alloys, and Cerium Compounds" in Ullmann's Encyclopedia of Industrial Chemistry 2000, Wiley-VCH, Weinheim. ] Due to the chemical similarities of the lanthanides, chemical separation is not usually required for their applications, such as the addition of mischmetal to steel as an inclusion modifier to improve mechanical properties, or as catalysts for the cracking of petroleum. This property of cerium saved the life of writer Primo Levi at the Auschwitz concentration camp, when he found a supply of ferrocerium alloy and bartered it for food.
Pigments and phosphors
The photostability of
can be enhanced by the addition of cerium, as it provides pigments with
lightfastness and prevents clear polymers from darkening in sunlight.
An example of a cerium compound used on its own as an inorganic pigment is the vivid red cerium(III) sulfide (cerium sulfide red), which stays chemically inert up to very high temperatures. The pigment is a safer alternative to lightfast but toxic
Cadmium pigments.
The addition of cerium oxide to older
cathode-ray tube television glass plates was beneficial, as it suppresses the darkening effect from the creation of
F-center defects due to the continuous electron bombardment during operation. Cerium is also an essential component as a
dopant for
used in CRT TV screens, fluorescent lamps, and later white light-emitting diodes.
[ Cerium dioxide . nanopartikel.info (2011-02-02)] The most commonly used example is (Ce:YAG) which emits green to yellow-green light (550–530 nm) and also behaves as a
scintillator.
Other uses
Cerium salts, such as the sulfides Ce
2S
3 and Ce
3S
4, were considered during the Manhattan Project as advanced
Refractory for the construction of crucibles which could withstand the high temperatures and strongly
Redox conditions when casting plutonium metal.
Despite desirable properties, these sulfides were never widely adopted due to practical issues with their synthesis.
Cerium is used as alloying element in aluminium to create castable eutectic
aluminium alloys with 6–16 wt.% Ce, to which other elements such as Mg, Ni, Fe and Mn can be added. These Al-Ce alloys have excellent high temperature strength and are suitable for automotive applications (e.g. in
).
Other alloys of cerium include Pu-Ce and Pu-Ce-Co plutonium alloys, which have been used as
nuclear fuel.
Other automotive applications for the lower sesquioxide are as a catalytic converter for the oxidation of CO and NOx emissions in the exhaust gases from motor vehicles.[Bleiwas, D.I. (2013). Potential for Recovery of Cerium Contained in Automotive Catalytic Converters. Reston, Va.: U.S. Department of the Interior, U.S. Geological Survey.]
Biological role and precautions
The early lanthanides have been found to be essential to some
methanotrophic bacteria living in
Mudpot, such as
Methylacidiphilum fumariolicum:
lanthanum,
cerium,
praseodymium, and
neodymium are about equally effective.
Cerium is otherwise not known to have biological role in any other organisms, but is not very toxic either; it does not accumulate in the food chain to any appreciable extent.
Because it often occurs together with calcium in phosphate minerals, and bones are primarily calcium phosphate, cerium can accumulate in bones in small amounts that are not considered dangerous.
Cerium nitrate is an effective topical antimicrobial treatment for third-degree burns,
Cerium oxide, the most prevalent cerium compound in industrial applications, is not regulated in the United States by the Occupational Safety and Health Administration (OSHA) as a hazardous substance.
Bibliography
